Galaxy record broken again

A cluster of galaxies nearly 10 billion years old

Though this cluster of galaxies (the red dots) is nearly 10 billion years old, it has a surprisingly modern appearance.

Using NASA’s Spitzer Space Telescope, a Texas A&M University-led team of astronomers has uncovered what may very well be the earliest, most distant cluster of galaxies ever detected.

The group of roughly 60 galaxies, called CLG J02182-05102, is nearly 10 billion years old — born just 4 billion years after the Big Bang.

This follows close on the heals of another distant galaxy cluster discovery.

However, it’s not the size nor the age of the cluster that amazes the team of researchers led by Dr Casey Papovich, an assistant professor in the Texas A&M Department of Physics and Astronomy. Rather, it’s the surprisingly modern appearance of CLG J02182-05102 that has them baffled — a huge, red collection of galaxies typical of only present-day galaxies.

“It’s like we dug an archaeological site in Rome and found pieces of modern Rome amongst the ruins,” explains Papovich.

While its neighbouring galaxies appear vastly smaller and far fainter, Papovich says CLG J02182-05102 stands out as a densely-populated bundle of ancient galaxies. Enormous, red galaxies at the centre contain almost 10 times as many stars as our Milky Way, he notes, combining for a total size which rivals that of the most monstrous galaxies of our nearby Universe.

Before now, Papovich says, such a finding would be considered by many astronomers to be highly unlikely, considering the time frame in which they were found.

“The predictions are that these things should be very rare when the Universe was 4 billion years old, and yet, we found them,” Papovich explains. “Not only did we find them, it looks for all intents and purposes like they had already formed completely and evolved into the large concentrations of galaxies that we see in clusters today.”

Exactly why these particular galaxies are fully formed that early is what Papovich and his collaborators — which include astronomers from NASA’s Jet Propulsion Laboratory at the California Institute of Technology (Caltech) as well as Carnegie Observatories — hope to one day uncover. But for now, studying CLG J02182-05102 could help them and other researchers better understand how galaxies form and cluster in general.

Galaxies with a rock ‘n’ roll lifestyle

Artist's impression of the Spitzer Space Telescope

Artist's impression of the Spitzer Space Telescope

The find resulted from a project initiated two years ago when Papovich and his team observed an area of the sky that could encompasses 250 full Moons, the largest extragalactic survey of space ever made — the Spitzer Wide-area InfraRed Extragalactic (SWIRE) survey.

The team focused on a cosmic region of the survey that previously had been observed by other instruments including Japan’s Subaru telescope on Mauna Kea, Hawaii, and the European Space Agency’s orbiting XMM-Newton telescope.

This, combined with infrared data from the United Kingdom Infrared Telescope — also in Hawaii — and Spitzer’s Public Ultra Deep Sky survey instantly revealed a number of distant galaxies.

It wasn’t until Papovich’s group studied faint light from CLG J02182-05102’s least-dim galaxies that they were able to determine they had found a cluster that contained about 60 galaxies full of old, red stars, at a time when the Universe was only 4 billion years old — about 30 percent of the Universe’s current age of 13.7 billion years.

At that point in time, most other galaxies would still have been forming their very first stars and certainly would not have congregated with other galaxies yet.

In essence, Papovich said the galaxies in CLG J02182-05102 must have subscribed to a rock ‘n’ roll lifestyle: They lived fast and died young. It’s another mystery Papovich hopes to solve through deeper observations, including spectroscopy, with the Hubble Telescope later this year.

“That’s one of the reasons this is so interesting,” he adds. “It seems that they somehow had a premonition they would end up in these big clusters, so that’s another thing we want to find out.”

Adapted from information issued by Texas A&M University / NASA / JPL-Caltech / C. Papovich (Texas A&M University) / Adam Hadhazy.

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